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Characteristics of the Genetic Variation of a Swamp Buffalo (Bubalusbubalis) of South Sumatra Based on Polymerase Chain Reaction- Random Amplified Polymorphic DNA (PCR- RAPD)
Yuanita Windusari1,*,Laila Hanum1, Arum Setiawan1,and Veronika Larasati1
1Department of Biology, Faculty of Mathematics and Natural Sciences, Universitas Sriwijaya, South
Sumatera
Abstract. Swamp buffalo (Bubalusbubalis) is one of the endemic species
that become a wealth of genetic resources of South Sumatra. This study
aims to the genetic variation and relationships of kinship 6 variants of
swamp buffalo South Sumatera. The methods used by the molecular
approach using RAPD-PCR primer 5 i.e. ILO 1204, ILO 1212, ILO 525,
OPW 03 and OPY 13. Data was analyzed using SPSS ver 16.0 and
presented in dendrogram. The results of the amplification, all primary
produce band with a total of 63 band of DNA (14.92%) with an average of
every primary produce 12.6 band of DNA. The most primary produce
DNA polymorphic bands namely OPW 03 (23.81%) and ILO 1204
(20.63%), while the primary ILO 525 (0.00%) do not generate
polymorphic bands. Genetic variation of swamp buffalo has a low genetic
variation with 14.92% percentage it generated polymorphic bands. The
results of the dendogram obtained two clusters namely cluster 1 included
Kerbau Tanduk Bulat, Kerbau Tanduk Langit, Kerbau Tanduk Melintang
and Kerbau Tanduk Dungkul, while the cluster 2 of them Kerbau Bule and
Kerbau Rebah Belakang. Swamp buffalo variants that have the closest
genetic distance. Kerbau Tanduk Langit and Kerbau Tanduk Bulat with
856 coefficient similarity, while the farthest Kerbau Tanduk Langit and
Kerbau Bule with the coefficient similarity -972. Swamp buffalo
(Bubalusbubalis) of South Sumatera, which consists of 6 variants of
buffalo have low genetic variation and inbreeding of closekinship.
1 Introduction
The population of swamp buffalo Pampangan South Sumatera adapts to monotonous
swamp areas that are not cultivated. Swamp buffalo Pampangan is a source of germplasm
was endemic to South Sumatera with low productivity and limited distribution which is one
of the genetic wealth of South Sumatera with OganIlir, Ogan Komering Ilir and Banyuasin
district [1]. The important role of buffaloes are very strategic in certain regions in
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© The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the CreativeCommons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).
Indonesia. Statistical data population in 2000 until 2008 shows buffalo livestock
populations did not increase and even tended to decline by 8.85% with an average rate of
decline of 1.03% per year. The influence of inbreeding on a large livestock on livestock
productivity. Inbreeding depression or inbreeding pressure on buffalo can usually cause a
decrease in the performance of livestock (growth), high mortality and low reproducibility.
One of the economic impacts of the high level of inbreeding is inbreeding depression where
there is a decrease in phenotypic averages, especially in traits that have high economic
value. The development of biotechnology at this point give a positive impact against
buffalo breeding and preservation in Indonesia are decrease each year. In line with the
development of the technology of DNA levels, then weakness identification with
morphological markers can be supported by a molecular approach. The use of molecular
markers in the form of DNA is used along with the development of the science of
molecular biology at this time[2].
Polymerase Chain Reaction (PCR) is a technique in molecular biology to multiply the
amount of DNA in-vitro fertilization using the enzyme DNA polymerase and temperature
[3]. The use of RAPD (Random Amplified Polymorphic DNA) is DNA analysis techniques
are becoming very popular todays. It is based on at the level of DNA [4]. The technique
were generally faster, cheaper than any other method for detecting DNA sequence variation
and does not require prior sequence information. The fact that RAPD’s survey multiple loci
in the genome makes the method attractive for analysis of genetic distance and phylogeny
reconstruction [5]. Diversity or genetic variation can be used as a starting point for
improving the quality and quantity of swamp buffalo. Thus, information about the genetic
crossbreeding and kinship in cattle including swamp buffalo is crucial in the preservation of
germplasm [6]. Genetic diversity became the important information in evaluating the
genetic potential for the development, utilization, and conservation of species[7].
2 Materials and Methods
Blood sampling place the swamp Buffalo (Bubalusbubalis) in the area of TanjungSenai,
Ogan Ilir Distrik, South Sumatera. Separation of serum is performed in the integrated
laboratory Postgraduate Sriwijaya University. The research of DNA isolation,
quantification of DNA and PCR-RAPD performed in the laboratory of Biochemistry at the
Faculty of biology of the Gajah Mada University.
Fig. 1. Sampling location
A total of 300 µl blood from 6 variants buffalo (Kerbau Bule, Kerbau Tanduk Bulat,
Kerbau Tanduk Langit, Kerbau Tanduk Melintang, Kerbau Tanduk Dungkul, Kerbau
Rebah Belakang) from 1 location were used in this study, with the number of samples for
each variant were 2individuals.
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2.1 Procedures of Quantity and Quality Test Results DNA Isolation
Before being used in the PCR reaction, DNA quantification is done to determine the
purity and concentration of DNA. Results of a DNA sample isolation, diluted as much as10 xin 0.2 ml tube with TE buffer, inserted into the as much as 1 µl sample DNA and added 9
µl of TE buffer. Then at homogeneous with spin down and spectrophotometer set at
wavelength of 260 nm, and washing kuvet with aquadest sterile then conducted measurements of blanko solution first. According to [8], quantitative DNA test with
spectrophotometry pure DNA can absorb ultraviolet light because of the existence of bases purin and pyrimidine. So the purity of DNA can be quantified by calculating the values of
absorbance 260 nm absorbance value divided by 280 (Å260/Å280) and the value of
DNA purity ranges between 1.8-2.0.
2.2 Electrophoresis
The results of the DNA isolation obtained then in gel electrophoresis by using agarose
1.5%, by dissolving 1.5 gram agarose with 100 ml of TBE 1x, and put in the microvawe
until dissolved. After a rather cold in the add 2 µl EtBr. Then prepared parafilm, as much as
2 µl DNA loading buffer (loading dye), then inserted 8 µl sample and mixed with a loading
buffer. Then, put in marker, DNA ladder 100 bp into wells. Electrode is then connected to a
power supply with a voltage of 100 Volt, ampere 400 speed for 30 minutes. Then the
agarose gel soaked in dye gel. Visualization is performed using the UV-transimulator to see
the results of electrophoresis. Then photographed as documentation [8].
2.3 PCR-RAPD
Observation 6 variants molecular done with phase DNA templates preparation, DNA
amplification, gel electrophoresis, gel electrophoresis quantification results, and data
analysis. Before being used in the process of PCR-RAPD primer beforehand suspended
using sterile aquabidest. Added with each primer 2x Master Mix PCR with 12,5 µL, Primer
RAPD (ILO- 1204, ILO-1212, ILO-525, OPW-03 and 2 µL OPY-13, 10,5 µL dH2O,
totalvolume of 25 µL to each microtube). The sample is then placed into the machine
performed as many as 30 cycles of PCR with pre-denaturation at 95°C for 5 minute,
denaturation at 95°C for 1 min, annealing at 55°C for 45 minutes, extention or elongation at
72°C for 1 minute, and final extention at 72°C for 10 minutes.
2.4 Visualization of Results Amplification
Visualization results of gel electrophoresis was conducted by using UV-
Transilluminator and the results photographed as documentation.
2.5 Data Analysis
Data obtained from RAPD method in the form of a band or bands of amplification
product was binary data represented by 'No (1) or no (0)'. DNA bands that have been
subsequently measured distance migration. Determining the size of the amplification of
DNA bands was done by measuring the migration distance of DNA standard (1 kb ladder)
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ranging from pitting to place the DNA migration. DNA fragment size standards then
created the algorithm, and the log is used as the Y axis while the migration distance of the
DNA used as the X axis measurable standards After the X and Y values are known then
made linear line equation Y = ax + b through linear regression line equation. The size of the
DNA bands are amplified searched by entering the measured values in the equation of the
line. Furthermore, the value of Y obtained and will be used as antilog long known bases are
amplified by a primer. After lengthy bases are known and obtained binary data is expressed
with 'No (1) or no (0)' [9], the data is then analyzed its genetic variation with the program
SPSS (Statistical Package for the Social Sciences) ver 16.0 and presented with a form of
cluster analysis, a dendogram using the coefficientsimilaritas.
3 Results and Discussions
Based on the results amplification of the swamp Buffalo (Bubalusbubalis) South
Sumatera based on PCR with RADP primary 5 (ILO 1204, ILO 1212, ILO 525, OPW
03and OPY 13) using 6 variant of the Buffalo swamp. The resulting DNA bands is
analyzed, then conducted by calculating the distance of migration of DNA. After that,if
there is a DNA bands in the give a score of (1) and there is no DNA bands in the give the
score (0). According with [10] that the DNA fragment pattern profiles of each primary
based on give the score or not the fragment using the binary code. Based on the scores are
then analyzed by using SPSS ver 16.0.
The results of the analysis kinship swamp buffalo South Sumatera by using SPSS
16.0 versi can be displayed in the form of a diagram called a dendogram. According [11],
that cluster formation process describes the dendogram expressed in form of pictures.
Horizontal lines above dendogram indicates scale that describes the level of similarity, the
smaller the scale value indicates the increasingly similar to thatindividual.
Fig. 2. Dendogram of swamp buffalo (Bubalusbubalis) South Sumatra based on PCR- RAPD
Description : (1) Kerbau Bule, (2) Kerbau Tanduk Bulat, (3) Kerbau Tanduk Langit, (4) Kerbau
Tanduk Melintang, (5) Kerbau Tanduk Dungkul, (6) Kerbau Rebah Belakang
The results of the analysis similarity matrix coefficients PCR-RAPD similarity between
6 variant of the swamp buffalo South Sumatera based on polymorphic DNA bands that 47
amplified similarity coefficients obtained with ranges of values -972 to 856. The value of
the lowest similarity coefficients -972 are indicated with the variant number 3 (Kerbau
Tanduk langit) with number 1 (Kerbau Bule) this indicates that due to the presence of the
genetic distance is far enough, while the highest coefficients value i.e. 856 indicated by
variant number 3 (Kerbau Tanduk Langit) and number 2 (Kerbau Tanduk Bulat), that is
because the genetic distance is close enough.
The value of the coefficient of 1.000 (100%) indicates that the absence of genetic
distance among the variants. It is in accordance with statement [12], that the value of the
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coefficient similarity 100% indicate that it is not just the distance between genetic variants
in one with the other variants. The smaller the distance its genetic then the higher its genetic
similarities instead its genetic distance is so large it will lower its genetic difference salso.
Based on the results of the analysis of the dendo gram can be seen that there are two
clusters namely cluster 1 that included Kerbau Tanduk Bulat, Kerbau Tanduk Langit,
Kerbau Tanduk Melintang and Kerbau Tanduk Dungkul, while the cluster 2 included
Kerbau Bule and Kerbau Rebah Belakang. Swamp Buffalo variants that have the closest
genetic distance is kerbau tanduk langit and kerbau tanduk bulat, while the farthest variants
kerbau tanduk langit and kerbau bule. According [10] to the genetic distance is the degree
of difference between the two populations and genes can be used in constructing
phylogenetic.
It is supported by research [13], about the relationship of kinship based on
morphological characteristics. Cluster 1 had the same character on the shape of the tip of
the horn, the color of the nose, eye, eyebrows eyelashes, color necklace neck and color hair
tail, while the cluster 2 has the same character on the color of the nose, ear, eye color, the
color of the lashes, the color of the body and tail of the hair color.
According to [14], that the population had a close kinship This indicates the occurrence
of inbreeding that can degrade the quality of genetic offspring, because it can increase
homozygosity populations. The level of genetic similarity of a population can be described
by the genetic distance of the individuals members of the population. The greater the
genetic distance of individuals in a population, then the population has members who are
increasingly diverse. Instead the smaller the genetic distance between individuals in a
population, the more uniform the population.
Based on those results show that swamp buffalos South Sumatera have low genetic
variation and genetic distance near or close relationship is suspected of inbreeding. It
agreed with [7], which stated the inbreeding suspected of causing a decrease in the nature
of phenotypes. Inbreeding among a variety of swamp Buffalo is certainly not only lowers
quality but also genotip and phenotypes. According to [6], that inbreeding affects the
productivity of the cattle. The low productivity of the herds of Buffalo are associated with
genetic reduction of occurrence prediction.
This is coherent with the research conducted by kinship of swamp Buffalo had previously
done by [15], that measures the of kinship based on morphology. The correlation
coefficient is 0.57 shows more kinship between swamp Buffalo post enumerates the
variance relatively close. Suspected cross between variants tend to be high. Advanced
research by [7], about genetic characteristics based on protein profile showed an average
value of results of all loci (H) 0.1286. Based on the average heterozygosity, swamp Buffalo
(Bubalusbubalis) Pampangan have low genetic variation and genetic relationship of the
nearest. Triwulaningsih (2005) in [16] states that traditional maintenance systems cause the
quality of buffalo seedlings to decline and result in the development of a slow population.
Indicators of the occurrence of inbreeding in buffalo livestock populations are characterized
by symptoms of genetic disorders / defects such as downward curved horns, and the high
incidence of albino.
[16] added that the influence of inbreeding on a large livestock on livestock
productivity. Inbreeding depression or inbreeding pressure on buffalo can usually cause a
decrease in the performance of livestock (growth), high mortality and low reproducibility.
One of the economic impacts of the high level of inbreeding is inbreeding depression where
there is a decrease in phenotypic averages, especially in traits that have high economic
value.
A follow-up study on the relationship of kinship according to [15], about diversity and
kinship swamp buffalo (Bubalusbubalis) Pampangan of South Sumatera based on
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morphological characteristics. The result of the analysis of kinship based on morphological
characteristics shows the correlation coefficient value of 0.85. Inbreeding and adaptation
factor cause the difference in phenotypes and morphology. A high level of inbreeding can
lead to inbreeding pressure which is characterized by a decrease in livestock production and
reproduction performance [17] which results in a decrease in the profits of livestock
businesses [18]. Some reports suspect the pressure of inbreeding in a population group that
results in a decrease in productivity and a slow increase in the livestock population.
According to [16] close relatives or inbreeding led to the emergence of recessive traits such
as albino. The factors that led to the occurrence of inbreeding in this group of livestock due
to closed populations, the inbreeding system was not directed, lack of knowledge about
breeders and male limitations. Based on those results can be that they variants swamp
buffalo Pampangan tend to be low due to inbreeding and adaptation to the environment that
result in differences of phenotype.
4 Conclusion
Genetic variation of swamp buffalo (Bubalusbubalis) has a low variation with the
percentage of polymorphic band 14.92 %. Swamp buffalo (Bubalusbubalis) South
Sumatera there are two clusters namely cluster 1 that included Kerbau Tanduk Bulat,
Kerbau Tanduk Langit, Kerbau Tanduk Melintang and Kerbau Tanduk Dungkul, while the
cluster 2 included Kerbau Bule and Kerbau Rebah Belakang. Kerbau tanduk langit and
kerbau tanduk bulat has a close kinship on coefficient of 856 while kerbau tanduk langit
and kerbau bule have a kinship with the farthest distance coefficient-972. To study the
characteristics of genetic diversity of swamp buffalo, it is necessary to use a different
approach
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